A system for energy storage and electricity generation is described. The system includes an energy storage subsystem and an electricity generation subsystem coupled to the energy storage subsystem. The energy storage subsystem is configured to store energy in the form of compressed air at a temperature greater than a temperature of ambient air in the atmosphere. The electricity generation subsystem includes an airlift pumping system and a hydro-electric power system driven by the airlift pumping system, and is configured to produce electricity by utilizing the compressed air stored in the energy storage subsystem at the temperature greater than the temperature of ambient air in the atmosphere.

A system for energy storage and electricity generation is described. The system includes an energy storage subsystem and an electricity generation subsystem coupled to the energy storage subsystem. The energy storage subsystem is configured to store energy in the form of compressed air at a temperature greater than a temperature of ambient air in the atmosphere. The electricity generation subsystem is configured to produce electricity by utilizing the compressed air stored in the energy storage subsystem at the temperature greater than the temperature of ambient air in the atmosphere.

A wind-water machine set is an evolving jet machine that moves the internal engine to the outside of the sleeve to work, instead of using a water jet as the main and air-jet as the auxiliary. When a ship uses multiple groups of wind-water machine set, there is a master control center for overall control and coordinated operation. Controlling the propulsion system makes the ship move forward and backward in an orderly manner. Control the surfing system to eliminate the bow water resistance and cooperate with the propulsion system. The steering control system is controlled to make the ship easy to operate the steering. Control the balance system to keep the ship balanced without swaying the roll angle. Control the draught system so that ships do not need ballast water. So that the ship can sail at super high speed, super fuel-efficient and safe.

A system for energy storage and electricity generation is described. The system includes an energy storage subsystem and an electricity generation subsystem coupled to the energy storage subsystem. The energy storage subsystem is configured to store energy in the form of compressed air at a temperature greater than a temperature of ambient air in the atmosphere. The electricity generation subsystem includes an airlift pumping system and a hydro-electric power system driven by the airlift pumping system, and is configured to produce electricity by utilizing the compressed air stored in the energy storage subsystem at the temperature greater than the temperature of ambient air in the atmosphere.

A system for energy storage and electricity generation is described. The system includes an energy storage subsystem and an electricity generation subsystem coupled to the energy storage subsystem. The energy storage subsystem is configured to store energy in the form of compressed air at a temperature greater than a temperature of ambient air in the atmosphere. The electricity generation subsystem is configured to produce electricity by utilizing the compressed air stored in the energy storage subsystem at the temperature greater than the temperature of ambient air in the atmosphere.

A wicket gate for a hydraulic turbine or pump contains a blade being defined by a pressure surface, an oppositely facing suction surface, a leading edge and a spaced apart trailing edge, a first trunnion, a second trunnion, an air inlet aperture, an air passage and at least one air outlet aperture. The profile of the suctions side surface of the blade along a cross section through a point P1 and a point P2 is concave. Whereas point P1 is located on the suction side surface of the trailing edge where an air outlet aperture is located and point P2 is spaced apart from point P1 by less than 10% of the wicket gate length D and point P2 is located upstream of point P1 on a line perpendicular to the trailing edge starting at point P1.

The present invention generally relates to hydraulic machinery, such as hydraulic turbines. More specifically, the invention is directed to optimizing power consumption when the turbine is used in condenser mode. The present invention provides a novel hydraulic installation where the reduction of pressure in the spiral case during condenser mode operations is more efficient, limiting the power consumption if compared to state-of-the-art installations.

A runner for a hydraulic turbine or pump includes a plurality of blades, each blade being defined by a pressure surface, an oppositely facing suction surface, a leading edge and a spaced apart trailing edge. At least one blade has a device for supplying a flow of oxygen containing gas to the trailing edge of at least one of the blades. The profile of the suction side surface of the blade along a cross section through a point P1 and a point P2 is concave. The point P1 is located on the suction side surface of the trailing edge where an opening is located, the point P2 is spaced apart from the point P1 by less than 3% of the runner outlet diameter D and the point P2 is located upstream of the point P1 on a line perpendicular to the trailing edge starting at the point P1.

A hydraulic machine has a runner of the Francis type, a head cover and a lower cover. A crown has a seal that seals the space between the crown and the head cover against water from the high pressure side. The runner is formed with at least one passage that is capable to drain high pressure leakage water passing the seal to the low pressure side. The passage is formed with an inlet aperture located in a portion of the crown which during operation is exposed to high pressure leakage water. The passage is located within one of the blades and leads from the inlet aperture to the band, where the passage forms an opening leading to the space between the band and the lower cover. The head cover is formed with an air inlet to admit air to the chamber between the head cover and the crown.

The present invention provides of a system for generating electricity from air hydropower. The system is having a pump from a reservoir. Also, at least one vessel for receiving pumped water therein, the at least one vessel having a pressure plate being buoyant over the water and pressurized pneumatically from other side to increase pressure over the water. The pressurized water is automised and released over the turbine for generating electricity. The system has an advantage of having less construction and maintenance cost by using very small area. Further, the system has an advantage of being converted from thermal power to air hydro power plant.